Section 2506. Flowable Mortar and Foamed Cellular Concrete
Place a flowable mortar fill material. Uses include, but are not limited to, placement
under existing bridges, around or within box culverts or culvert pipes, in open
trenches, or at other locations as shown in the contract documents. Foamed cellular concrete may be used at the Contractor’s
option.
Meet the requirements for the respective items in Division 41 with the following exceptions:
Meet the requirements of Section 4101.
Meet the requirements of Section 4108. Use fly ash from a source approved by the Engineer.
1. Use natural sand consisting of mineral aggregate particles or foundry sand from the castings of ferrous material. Use the gradation shown in Table 2506.02-1:
Table 2506.02-1: Fine Aggregate Gradation |
|
Sieve Size |
Percent Passing |
3/8 inch No. 200 |
100 0-10 |
2. It is intended that the sand be a fine sand that will stay in suspension in the mortar to the extent required for proper flow. For the Contractor's information, a well graded sand in the gradation range shown in Table 2506.02-2 has generally shown good flow characteristics when using the normal amount of fly ash (300 pounds per cubic yard). Concrete sand may require a higher amount of fly ash (400 pounds per cubic yard) and air entrainment to produce the desired flowability.
Table 2506.02-2: Informational Gradation Limits |
|
Sieve Size |
Percent Passing |
3/8 inch No. 8 No. 16 No. 30 No. 50 No. 100 No. 200 |
100 80-100 60-100 45-80 12-40 1.5-25 0-5 |
3. If foundry sand is used, ensure it meets the requirements of IAC 567 Section 108. Ensure suppliers of foundry sand submit a processing plan to the District Materials Engineer for review and approval.
1. Air entraining and water reducing admixtures may be added to increase the fluidity of flowable mortar.
2. Use preformed foam meeting the requirements of ASTM C 869 for foamed cellular concrete when tested in accordance with ASTM C 796.
1. Flowable Mortar.
1 a. For non critical fluidity, use the basic
proportioning for flowable mortar shown in Table 2506.02-3:
Table 2506.02-3: Quantities of Dry Materials Per Cubic Yard for Non-Critical Fluidity |
|
Cement Fly Ash Fine Aggregate |
100 pounds 300 pounds 2600 pounds |
Previous or alternate mix designs may be approved by the District Materials Engineer.
2 b. For critical fluidity, use the basic
proportioning as shown in Table 2506.02-4.
Table 2506.02-4: Quantities of Dry Materials Per Cubic Yard for Critical Fluidity |
|
Cement Fly Ash Fine Aggregate |
100 pounds 400 pounds 2600 pounds |
a.1) Provide Engineer with mix proportions
meeting requirements in Article
2506.02, F. Do not exceed 100 pounds
of cement per cubic yard and a total amount of cementitious material of 500
pounds per cubic yard.
b.2) When the design includes air entraining and water reducing admixtures,
Engineer may approve the design without laboratory testing. Engineer may
require representative materials for evaluation before approval. When required,
one week before work begins, submit samples of fine aggregate, cement, and fly
ash intended for use to the Engineer.
c.3) Previous mix
designs for critical flow may be approved by the District Materials Engineer.
These mixes may also be used for non critical flow.
3 c. These quantities of dry materials, with approximately
70 gallons of water (mixes utilizing foundry sand may require more water), will
yield approximately 1 cubic yard of flowable mortar of the proper consistency.
The quantity of water used for the trial mix or at the project may require
adjustment to achieve proper solids suspension and optimum flowability.
4 d. For information, volume loss during the cure period
resulting from surface evaporation, moisture migration away from the flowable
mortar unit, and hydration have been observed to be less than 4% of the
original volume determined in the fluid condition. In mixes utilizing foundry
sand, additional fly ash may be required and the limit of total cementitious
material will not apply.
2. Foamed Cellular Concrete.
a. Use foamed cellular concrete with a minimum compressive strength of 100 psi.
b. Use high density cellular concrete with a minimum of 70 pounds per cubic foot for placement under existing bridges, applications placed below water table, or in annular pipe space that cannot be dewatered. Fine aggregate may be included.
c. Use low density cellular concrete with a minimum of 30 pounds per cubic foot for applications above water table or if no water is present in annular pipe space.
d. Submit mix design to the DME. Include base cement slurry mix per cubic yard, expansion factor from the foaming agent, and wet density.
1. Measure the fluidity of the flowable mortar using the method described by Materials I.M. 375. Prior to filling the flow cone with flowable mortar, pass the mixture through a 1/4 inch screen.
2. In locations where fluidity is critical, such as inside existing culverts and between the beams under existing bridges, use an efflux time of 10 seconds to 16 seconds. The Engineer will measure prior to placement and at least once every 4 working hours until work is complete.
3. In locations where fluidity is not critical, such as for placement below the beams under existing bridges or for use as backfill material in open trenches, the Engineer will visually monitor. Provide sufficient fluidity to completely fill the space and produce a level surface without manipulation after discharge.
4. Fluidity measurement is not required for foamed cellular concrete.
G. Granular Backfill Material.
For granular backfill material used under flowable mortar, meet the requirements of Section 4133. Granular backfill is not required for foamed cellular concrete.
A. Proportioning and Mixing Equipment.
1. Use equipment meeting the requirements of Articles 2001.20 and 2001.21. Provide mixers with sufficient mixing capacity to permit the intended placement without interruption.
2. For foamed cellular concrete, use foam generating equipment capable of producing proper volume of foam and injecting foam into truck mixer drum. Alternatively, a mobile batch plant capable of mixing and pumping foamed cellular concrete to within 10% of the design density and a minimum capacity of 1 cubic yard.
When the flowable mortar is to be placed under a bridge, cover the bridge beams with a filler material, as shown in the contract documents, to fill the flange areas in a manner that will minimize intrusion of the mortar into the flange area of the beams. Construction insulation board or any other suitable material may be used.
C. Placement of Mortar under Existing Bridges.
1. First construct the shoulder area as shown in the contract documents, with the drainage system shown. Complete this work in conjunction with pipe placement, if a pipe culvert is required.
2. If a culvert is required, place engineering fabric meeting requirements of Article 4196.01, B, 2 over all joints in the culvert, within the area where flowable mortar is to be placed as backfill material. Place the fabric from the underlying ground line around the culvert, 1 foot on each side of the joint.
3. Discharge flowable mortar from the mixer by any reasonable means into the area to be filled.
4. Bring the mortar fill up uniformly to the elevation of the first stage fill line, if specified. Cease mortar placement for a period of 72 hours.
5. If there is only one stage of flowable mortar, place granular backfill material in the lower part of the fill and around the pipe as specified. Compact the granular backfill material according to Article 2402.03, H, or thoroughly and uniformly wet with water in a quantity of approximately 10% of the granular backfill material. Complete flooding may be required. Regardless of the method of consolidation, wait 72 hours to commence flowable mortar placement.
6. Place the flowable mortar in a sequential operation from side to side and longitudinally. Begin with fill in one shoulder area, then proceed through each hole in the deck adjacent to the shoulder until mortar is expelled from the adjacent longitudinal hole. Place the last fill on the opposite shoulder. Place mortar through holes in the deck using a suitable funnel which can create a 3 foot head during filling.
7. The locations for holes in the deck will normally be shown in the contract documents. When not shown, drill a hole approximately 5 feet from each end of the bridge in each area between bridge beams. Drill additional holes as necessary so the longitudinal spacing does not exceed 20 feet. Limit the size of the holes to that necessary to accommodate filling equipment.
8. When placement of flowable mortar is completed and set, remove the mortar in the holes in the deck and replace with a suitable PCC mixture.
D. Placement of Mortar as Culvert Backfill Material.
1. First construct the shoulder area with suitable soil as shown in the contract documents, with the drainage system shown. Complete this work in conjunction with the pipe placement, if the culvert is a pipe.
2. Place engineering fabric meeting requirements of Article 4196.01, B, 2 over all joints in the culvert, within the area where flowable mortar is to be placed as backfill material. Place the fabric from the underlying ground line around the culvert, 1 foot on each side of the joint.
3. Place granular backfill material meeting requirements of Section 4133 to approximately mid-height of the culvert. Place the backfill simultaneously on both sides of the culvert so that the two fills are kept at approximately the same elevation at all times. Granular backfill material compaction is not necessary.
4. Discharge flowable mortar from the mixer into the remaining area to be filled. Fill simultaneously on both sides of the structure so that the two fills are kept at approximately the same elevation at all times.
5. If the culvert starts to float, cease the filling operation. Apply an external load to the culvert, sufficient to hold it in place, before the filling is continued. As an alternate, the filling may be suspended until the buoyancy effect of the mortar has ceased.
6. Place the flowable mortar to the elevation shown in the contract documents. When not shown, place the mortar as follows:
a. If the subgrade elevation is not more than 5 feet over the top of the culvert, place mortar to 1 foot below subgrade elevation.
b. If the subgrade is more than 5 feet over the top of the culvert, place the mortar to an elevation 2 feet over the top of the culvert. Complete the remainder of the backfill operation using soil designated by the Engineer.
1. Flowable Mortar.
Fill all voids between the liner pipe and the host culvert with flowable mortar. Staged grouting is recommended. Ensure that all voids between the liner pipe and host pipe have been filled with flowable mortar by providing 2 feet of head when filling.
2. Foamed Cellular Concrete
a. Construct bulkheads at each end of the pipe. Ensure bulkhead is constructed to withstand pressure of grouting operation.
b. Use grouting pressures to ensure all voids between the liner pipe and host pipe have been filled, but do not collapse or deform the liner pipe by more than 5% of the diameter. Multiple grout lifts may be necessary in accordance with pipe manufacturer’s recommendations.
c. Contractor shall check wet density at the beginning of the placement and a minimum of once every 2 hours and results will be documented by the Engineer.
d. If grout holes are utilized, insert cylindrical wood plugs, or other approved plugs, until the grout has set. Fill holes with concrete after plugs have been removed.
E F.
Limitation of Operations.
1.
Do not place flowable mortar on frozen ground.
2.
Flowable
mortar bBatching, mixing,
and placing may be started when the temperature is at least 34°F and rising, if
weather conditions are favorable. At time of placement, mortar shall have a
temperature of at least 40°F. Cease mixing and placing when the temperature is
38°F or less and falling.
3. Complete each filling stage in as continuous an operation as practical.
4. Do not allow flowable mortar or foamed cellular concrete into streams and waterways.
2506.04 method of measurement.
A. The Engineer will compute the volume of Flowable Mortar furnished and placed, from the nominal volume of each batch and a count of batches. The Engineer will estimate and deduct unused mortar; however, deduction will not be made for a partial batch remaining at the completion of the operation. Foamed cellular concrete may be substituted at the Contractor’s option at no additional cost to the Contracting Authority.
B. Granular backfill material used in the lower part of the fill area for projects utilizing flowable mortar will be based on the contract document quantity.
C. When the flowable mortar elevation for placing backfill around culverts is shown in the contract documents, payment for Flowable Mortar will be based on the quantity shown in the contract documents.
A. Payment for Flowable Mortar will be the contract unit price per cubic yard. Foamed cellular concrete may be substituted at the Contractor’s option at no additional cost to the Contracting Authority.
B. Payment is full compensation for:
· Placing the flowable mortar or foamed cellular concrete,
· Flange filler material,
· Engineering fabric as required,
· Drilling and filling the bridge deck holes, and
· Furnishing all materials, equipment, and labor necessary to complete the work.
C. Payment for granular backfill material used in the lower part of the fill area
will be based on the quantity shown in the
contract documents, and this will normally be included in the quantity of other
granular backfill material on the project per Article 2402.05, G.
D. Excavation, placing backfill material for construction of the shoulder area, and moisture control if designated necessary for this work, will be paid for separately. These items will be included in the quantities of other similar work on the project. Furnishing and placing the drainage system in the shoulder area will be considered incidental to the payment for Flowable Mortar.